/* Copyright (C) 2001-2020 Artifex Software, Inc. All Rights Reserved. This software is provided AS-IS with no warranty, either express or implied. This software is distributed under license and may not be copied, modified or distributed except as expressly authorized under the terms of the license contained in the file LICENSE in this distribution. Refer to licensing information at http://www.artifex.com or contact Artifex Software, Inc., 1305 Grant Avenue - Suite 200, Novato, CA 94945, U.S.A., +1(415)492-9861, for further information. */ /* Path stroking procedures for Ghostscript library */ #include "math_.h" #include /* abs() */ #include "gx.h" #include "gpcheck.h" #include "gserrors.h" #include "gsdcolor.h" #include "gsptype1.h" #include "gxfixed.h" #include "gxfarith.h" #include "gxmatrix.h" #include "gscoord.h" #include "gsdevice.h" #include "gxdevice.h" #include "gxhttile.h" #include "gxgstate.h" #include "gzline.h" #include "gzpath.h" #include "gzcpath.h" #include "gxpaint.h" #include "gsstate.h" /* for gs_currentcpsimode */ /* RJW: There appears to be a difference in the xps and postscript models * (at least in as far as Microsofts implementation of xps and Acrobats of * postscript). Acrobat (and ghostscript) are happy to join a line segment * around a corner, even when the next segment is a dash gap. Microsofts * implementation of XPS does not. * * A test file that shows this up is tests_private/comparefiles/298-05.ps * * Enabling the following define would emulate xps behaviour here. */ #undef AVOID_JOINING_TO_DASH_GAPS /* * We don't really know whether it's a good idea to take fill adjustment * into account for stroking. Disregarding it means that strokes * come out thinner than fills; observing it produces heavy-looking * strokes at low resolutions. But in any case, we must disregard it * when stroking zero-width lines. */ #define USE_FILL_ADJUSTMENT #ifdef USE_FILL_ADJUSTMENT # define STROKE_ADJUSTMENT(thin, pgs, xy)\ (thin ? fixed_0 : (pgs)->fill_adjust.xy) #else # define STROKE_ADJUSTMENT(thin, pgs, xy) fixed_0 #endif /* * For some reason, we commented out the optimization for portrait, * landscape, and uniform (non-scaled) transformations. We have no record * of why we did this, and we don't know what bugs re-enabling it may * introduce. */ #define OPTIMIZE_ORIENTATION /* * Compute the amount by which to expand a stroked bounding box to account * for line width, caps and joins. Return 0 if the result is exact, 1 if * it may be conservative, or gs_error_limitcheck if the result is too * large to fit in a gs_fixed_point. * * Because of square caps and miter and triangular joins, the maximum * expansion on each side (in user space) is * K * line_width/2 * where K is determined as follows: * For round or butt caps, E = 1 * For square caps, E = sqrt(2) * If the path is only a single line segment, K = E; * if triangular joins, K = 2; * if miter joins, K = max(miter_limit, E); * otherwise, K = E. * * If the following conditions apply, K = E yields an exact result: * - The CTM is of the form [X 0 0 Y] or [0 X Y 0]. * - Square or round caps are used, or all subpaths are closed. * - All segments (including the implicit segment created by * closepath) are vertical or horizontal lines. * * Note that these conditions are sufficient, but not necessary, to get an * exact result. We choose this set of conditions because it is easy to * check and covers many common cases. Clients that care always have the * option of using strokepath to get an exact result. */ static float join_expansion_factor(const gs_gstate *, gs_line_join); int gx_stroke_path_expansion(const gs_gstate * pgs, const gx_path * ppath, gs_fixed_point * ppt) { const subpath *psub; const segment *pseg; double cx = fabs(pgs->ctm.xx) + fabs(pgs->ctm.yx); double cy = fabs(pgs->ctm.xy) + fabs(pgs->ctm.yy); double expand = pgs->line_params.half_width; int result = 1; if (ppath == NULL) { ppt->x = ppt->y = 0; return 0; /* no expansion */ } psub = ppath->first_subpath; /* Adjust the expansion (E) for square caps, if needed */ if (pgs->line_params.start_cap == gs_cap_square || pgs->line_params.end_cap == gs_cap_square) expand *= 1.414213562; /* Check for whether an exact result can be computed easily. */ if (is_fzero2(pgs->ctm.xy, pgs->ctm.yx) || is_fzero2(pgs->ctm.xx, pgs->ctm.yy) ) { bool must_be_closed = !(pgs->line_params.start_cap == gs_cap_square || pgs->line_params.start_cap == gs_cap_round || pgs->line_params.end_cap == gs_cap_square || pgs->line_params.end_cap == gs_cap_round || pgs->line_params.dash_cap == gs_cap_square || pgs->line_params.dash_cap == gs_cap_round); gs_fixed_point prev; prev.x = prev.y = 0; /* Quiet gcc warning. */ for (pseg = (const segment *)psub; pseg; prev = pseg->pt, pseg = pseg->next ) switch (pseg->type) { case s_start: if (((const subpath *)pseg)->curve_count || (must_be_closed && !((const subpath *)pseg)->is_closed) ) goto not_exact; break; case s_line: case s_dash: case s_line_close: if (!(pseg->pt.x == prev.x || pseg->pt.y == prev.y)) goto not_exact; break; case s_gap: default: /* other/unknown segment type */ goto not_exact; } result = 0; /* exact result */ } not_exact: if (result) { if (!gx_path_has_curves(ppath) && gx_path_subpath_count(ppath) <= 1 && (psub == 0 || (pseg = psub->next) == 0 || (pseg = pseg->next) == 0 || pseg->type == s_line_close)) DO_NOTHING; else { float factor = join_expansion_factor(pgs, pgs->line_params.join); if (pgs->line_params.curve_join >= 0) factor = max(factor, join_expansion_factor(pgs, (gs_line_join)pgs->line_params.curve_join)); expand *= factor; } } /* Short-cut gs_bbox_transform. */ { float exx = expand * cx; float exy = expand * cy; int code = set_float2fixed_vars(ppt->x, exx); if (code < 0) return code; code = set_float2fixed_vars(ppt->y, exy); if (code < 0) return code; } return result; } static float join_expansion_factor(const gs_gstate *pgs, gs_line_join join) { switch (join) { case gs_join_miter: return pgs->line_params.miter_limit; case gs_join_triangle: return 2.0; default: return 1.0; } } /* * Structure for a partial line (passed to the drawing routine). * Two of these are required to do joins right. * Each endpoint includes the two ends of the cap as well, * and the deltas for square, round, and triangular cap computation. * * The two base values for computing the caps of a partial line are the * width and the end cap delta. The width value is one-half the line * width (suitably transformed) at 90 degrees counter-clockwise * (in device space, but with "90 degrees" interpreted in *user* * coordinates) at the end (as opposed to the origin) of the line. * The cdelta value is one-half the transformed line width in the same * direction as the line. From these, we compute two other values at each * end of the line: co and ce, which are the ends of the cap. * Note that the cdelta values at o are the negatives of the values at e, * as are the offsets from p to co and ce. * * Initially, only o.p, e.p, e.cdelta, width, and thin are set. * compute_caps fills in the rest. */ typedef gs_fixed_point *p_ptr; typedef struct endpoint_s { gs_fixed_point p; /* the end of the line */ gs_fixed_point co, ce; /* ends of the cap, p +/- width */ gs_fixed_point cdelta; /* +/- cap length */ } endpoint; typedef endpoint *ep_ptr; typedef const endpoint *const_ep_ptr; typedef struct partial_line_s { endpoint o; /* starting coordinate */ endpoint e; /* ending coordinate */ gs_fixed_point width; /* one-half line width, see above */ gs_fixed_point vector; /* The line segment direction */ bool thin; /* true if minimum-width line */ } partial_line; typedef partial_line *pl_ptr; /* As we stroke a path, we run through the line segments that make it up. * We gather each line segment together with any degenerate line segments * that follow it (call this set "prev"), and then 'join them' to the next * line segment (and any degenerate line segments that follow it) (if there * is one) (call this "current"). * * In order to get the joins right we need to keep flags about both * prev and current, and whether they originally came from arcs. */ typedef enum note_flags { /* If set, all the line segments that make up current come from arcs. */ nf_all_from_arc = 1, /* If set, at least one of the line segments that make up current, come * from arcs. */ nf_some_from_arc = 2, /* If set then this segment should have a dash cap on the start rather * than a start cap. */ nf_dash_head = 4, /* If set then this segment should have a dash cap on the end rather * than an end cap. */ nf_dash_tail = 8, /* If set, all the line segments that make up prev come from arcs. */ nf_prev_all_from_arc = 16, /* If set, at least one of the line segment that make up prev, come from * arcs. */ nf_prev_some_from_arc = 32, /* If set then prev should have a dash cap on the start rather * than a start cap. */ nf_prev_dash_head = 64, /* If set then prev should have a dash cap on the end rather * than an end cap. */ nf_prev_dash_tail = 128 } note_flags; /* Macro to combine the prev and current arc_flags. After applying this * macro, the bits in the result have the following meanings: * nf_all_from_arc set if all the components of current and prev * come from an Arc. * nf_some_from_arc set if any of the components of current and * prev come from an Arc. * nf_dash_head set if prev should have a dash cap rather than * a start cap. * nf_dash_tail set if prev should have a dash cap rather than * an end cap. */ #define COMBINE_FLAGS(F) \ (((F>>4) | ((F) & nf_some_from_arc)) & \ (((F) & nf_all_from_arc) ? ~0 : ~nf_all_from_arc)) /* Assign a point. Some compilers would do this with very slow code */ /* if we simply implemented it as an assignment. */ #define ASSIGN_POINT(pp, p)\ ((pp)->x = (p).x, (pp)->y = (p).y) /* Other forward declarations */ static bool width_is_thin(pl_ptr); static void adjust_stroke(gx_device *, pl_ptr, const gs_gstate *, bool, bool, note_flags); static int line_join_points(const gx_line_params * pgs_lp, pl_ptr plp, pl_ptr nplp, gs_fixed_point * join_points, const gs_matrix * pmat, gs_line_join join, bool reflected); static int line_join_points_fast_cw(const gx_line_params * pgs_lp, pl_ptr plp, pl_ptr nplp, gs_fixed_point * rjoin_points, const gs_matrix * pmat, gs_line_join join); static int line_join_points_fast_ccw(const gx_line_params * pgs_lp, pl_ptr plp, pl_ptr nplp, gs_fixed_point * join_points, const gs_matrix * pmat, gs_line_join join); static void compute_caps(pl_ptr); static int add_points(gx_path *, const gs_fixed_point *, int, bool); static int add_pie_join(gx_path *, pl_ptr, pl_ptr, bool, bool); static int add_pie_join_fast_cw(gx_path *, pl_ptr, pl_ptr, bool); static int add_pie_join_fast_ccw(gx_path *, pl_ptr, pl_ptr, bool); static int add_round_cap(gx_path *, const_ep_ptr); static int add_pie_cap(gx_path *, const_ep_ptr); static int cap_points(gs_line_cap, const_ep_ptr, gs_fixed_point * /*[3] */ ); static int join_under_pie(gx_path *, pl_ptr, pl_ptr, bool); /* Define the default implementation of the device stroke_path procedure. */ int gx_default_stroke_path(gx_device * dev, const gs_gstate * pgs, gx_path * ppath, const gx_stroke_params * params, const gx_drawing_color * pdcolor, const gx_clip_path * pcpath) { return gx_stroke_path_only(ppath, (gx_path *) 0, dev, pgs, params, pdcolor, pcpath); } /* Fill a partial stroked path. Free variables: */ /* to_path, stroke_path_body, fill_params, always_thin, pgs, dev, pdevc, */ /* code, ppath, exit(label). */ #define FILL_STROKE_PATH(dev, thin, pcpath, final)\ if(to_path==&stroke_path_body && !gx_path_is_void(&stroke_path_body) &&\ (final || lop_is_idempotent(pgs->log_op))) {\ fill_params.adjust.x = STROKE_ADJUSTMENT(thin, pgs, x);\ fill_params.adjust.y = STROKE_ADJUSTMENT(thin, pgs, y);\ if (to_path_reverse != NULL) {\ code = gx_join_path_and_reverse(to_path, to_path_reverse);\ if(code < 0) goto exit;\ }\ code = gx_fill_path_only(to_path, dev, pgs, &fill_params, pdevc, pcpath);\ gx_path_free(&stroke_path_body, "fill_stroke_path");\ if ( code < 0 ) goto exit;\ gx_path_init_local(&stroke_path_body, ppath->memory);\ } /* * Define the internal procedures that stroke a partial_line * (the first pl_ptr argument). If both partial_lines are non-null, * the procedure creates an appropriate join; otherwise, the procedure * creates an end cap. If the first int is 0, the procedure also starts * with an appropriate cap. */ #define stroke_line_proc(proc)\ int proc(gx_path *, gx_path *, bool ensure_closed, int, pl_ptr, pl_ptr,\ const gx_device_color *, gx_device *, const gs_gstate *,\ const gx_stroke_params *, const gs_fixed_rect *, int,\ gs_line_join, bool, note_flags) typedef stroke_line_proc((*stroke_line_proc_t)); static stroke_line_proc(stroke_add); static stroke_line_proc(stroke_add_compat); static stroke_line_proc(stroke_add_fast); static stroke_line_proc(stroke_fill); static int stroke_add_initial_cap_compat(gx_path * ppath, pl_ptr plp, bool adlust_longitude, const gx_device_color * pdevc, gx_device * dev, const gs_gstate * pgs); /* Define the orientations we handle specially. */ typedef enum { orient_other = 0, orient_portrait, /* [xx 0 0 yy tx ty] */ orient_landscape /* [0 xy yx 0 tx ty] */ } orientation; /* * Internal function used to merge the 2 sides of a stroked path. * path contains the 'forward' side, rpath contains the 'reversed' side. * Reverse rpath, then append it to path. * * If path is closed, then rpath should be too. If path is open, then the * starting and ending points of both paths should be the same, so as to * guarantee a closed path. */ static int gx_join_path_and_reverse(gx_path * path, gx_path * rpath) { int code; if (gx_path_is_void(rpath)) return 0; code = gx_path_append_reversed(rpath, path); if (code < 0) return code; gx_path_free(rpath, "gx_join_path_and_reverse"); gx_path_init_local(rpath, path->memory); return gx_path_close_subpath(path); } /* * Stroke a path. If to_path != 0, append the stroke outline to it; * if to_path == 0, draw the strokes on pdev. * * Note that gx_stroke_path_only with to_path != NULL may clip the path to * the clipping path, as for to_path == NULL. This is almost never * what is wanted. */ static int gx_stroke_path_only_aux(gx_path * ppath, gx_path * to_path, gx_device * pdev, const gs_gstate * pgs, const gx_stroke_params * params, const gx_device_color * pdevc, const gx_clip_path * pcpath) { bool CPSI_mode = gs_currentcpsimode(pgs->memory); bool traditional = CPSI_mode | params->traditional; stroke_line_proc_t line_proc = ((to_path == 0 && !gx_dc_is_pattern1_color_clist_based(pdevc)) ? (lop_is_idempotent(pgs->log_op) ? stroke_fill : stroke_add) : (traditional ? stroke_add_compat : stroke_add_fast)); gs_fixed_rect ibox, cbox; gx_device_clip cdev; gx_device *dev = pdev; int code = 0; gx_fill_params fill_params; const gx_line_params *pgs_lp = gs_currentlineparams_inline(pgs); int dash_count = pgs_lp->dash.pattern_size; gx_path fpath, dpath; gx_path stroke_path_body; gx_path stroke_path_reverse; gx_path *to_path_reverse = NULL; const gx_path *spath; float xx = pgs->ctm.xx, xy = pgs->ctm.xy; float yx = pgs->ctm.yx, yy = pgs->ctm.yy; /* * We are dealing with a reflected coordinate system * if transform(1,0) is counter-clockwise from transform(0,1). * See the note in stroke_add for the algorithm. */ int uniform; bool reflected; orientation orient = ( #ifdef OPTIMIZE_ORIENTATION is_fzero2(xy, yx) ? (uniform = (xx == yy ? 1 : xx == -yy ? -1 : 0), reflected = (uniform ? uniform < 0 : (xx < 0) != (yy < 0)), orient_portrait) : is_fzero2(xx, yy) ? (uniform = (xy == yx ? -1 : xy == -yx ? 1 : 0), reflected = (uniform ? uniform < 0 : (xy < 0) == (yx < 0)), orient_landscape) : /* We should optimize uniform rotated coordinate systems */ /* here as well, but we don't. */ #endif (uniform = 0, reflected = xy * yx > xx * yy, orient_other)); const segment_notes not_first = sn_not_first; gs_line_join curve_join = (pgs_lp->curve_join >= 0 ? (gs_line_join)pgs_lp->curve_join : pgs_lp->join == gs_join_none || pgs_lp->join == gs_join_round ? gs_join_bevel : pgs_lp->join); float line_width = pgs_lp->half_width; /* (*half* the line width) */ bool always_thin; double line_width_and_scale; double device_line_width_scale = 0; /* Quiet compiler. */ double device_dot_length = pgs_lp->dot_length * fixed_1; const subpath *psub; gs_matrix initial_matrix; bool initial_matrix_reflected; note_flags flags; (*dev_proc(pdev, get_initial_matrix)) (pdev, &initial_matrix); initial_matrix_reflected = initial_matrix.xy * initial_matrix.yx > initial_matrix.xx * initial_matrix.yy; #ifdef DEBUG if (gs_debug_c('o')) { int i; dmlprintf4(ppath->memory, "[o]half_width=%f, start_cap=%d, end_cap=%d, dash_cap=%d,\n", pgs_lp->half_width, (int)pgs_lp->start_cap, (int)pgs_lp->end_cap, (int)pgs_lp->dash_cap); dmlprintf3(ppath->memory, " join=%d, miter_limit=%f, miter_check=%f,\n", (int)pgs_lp->join, pgs_lp->miter_limit, pgs_lp->miter_check); dmlprintf1(ppath->memory, " dash pattern=%d", dash_count); for (i = 0; i < dash_count; i++) dmprintf1(ppath->memory, ",%f", pgs_lp->dash.pattern[i]); dmputs(ppath->memory, ",\n"); dmlprintf4(ppath->memory, "\toffset=%f, init(ink_on=%d, index=%d, dist_left=%f)\n", pgs_lp->dash.offset, pgs_lp->dash.init_ink_on, pgs_lp->dash.init_index, pgs_lp->dash.init_dist_left); } #endif gx_path_bbox(ppath, &ibox); /* Expand the path bounding box by the scaled line width. */ { gs_fixed_point expansion; if (gx_stroke_path_expansion(pgs, ppath, &expansion) < 0) { /* The expansion is so large it caused a limitcheck. */ ibox.p.x = ibox.p.y = min_fixed; ibox.q.x = ibox.q.y = max_fixed; } else { expansion.x += pgs->fill_adjust.x; expansion.y += pgs->fill_adjust.y; /* * It's theoretically possible for the following computations to * overflow, so we need to check for this. */ ibox.p.x = (ibox.p.x < min_fixed + expansion.x ? min_fixed : ibox.p.x - expansion.x); ibox.p.y = (ibox.p.y < min_fixed + expansion.y ? min_fixed : ibox.p.y - expansion.y); ibox.q.x = (ibox.q.x > max_fixed - expansion.x ? max_fixed : ibox.q.x + expansion.x); ibox.q.y = (ibox.q.y > max_fixed - expansion.y ? max_fixed : ibox.q.y + expansion.y); } } /* Check the expanded bounding box against the clipping regions. */ if (pcpath) gx_cpath_inner_box(pcpath, &cbox); else if (pdevc) (*dev_proc(pdev, get_clipping_box)) (pdev, &cbox); else { /* This is strokepath, not stroke. Don't clip. */ cbox = ibox; } if (!rect_within(ibox, cbox)) { /* Intersect the path box and the clip bounding box. */ /* If the intersection is empty, this call is a no-op. */ gs_fixed_rect bbox; if (pcpath) { gx_cpath_outer_box(pcpath, &bbox); if_debug4m('f', ppath->memory, " outer_box=(%g,%g),(%g,%g)\n", fixed2float(bbox.p.x), fixed2float(bbox.p.y), fixed2float(bbox.q.x), fixed2float(bbox.q.y)); rect_intersect(ibox, bbox); } else rect_intersect(ibox, cbox); if (ibox.p.x >= ibox.q.x || ibox.p.y >= ibox.q.y) { /* Intersection of boxes is empty! */ return 0; } /* * The path is neither entirely inside the inner clip box * nor entirely outside the outer clip box. * If we had to flatten the path, this is where we would * recompute its bbox and make the tests again, * but we don't bother right now. */ /* * If there is a clipping path, set up a clipping device. * for stroke_fill because, because the latter uses low level methods * which don't accept a clipping path. * Note that in some cases stroke_fill appends the path to stroke_path_body * instead a real painting, and it is painted with FILL_STROKE_PATH. * * Contrary to that, FILL_STROKE_PATH paints a path with * the fill_path method, which handles a clipping path, * so we don't pass the clipper device to FILL_STROKE_PATH * to prevent an appearence of superposing clippers. */ if (pcpath && line_proc == stroke_fill) { gx_make_clip_device_on_stack(&cdev, pcpath, pdev); cdev.max_fill_band = pdev->max_fill_band; dev = (gx_device *)&cdev; } } fill_params.rule = gx_rule_winding_number; fill_params.flatness = pgs->flatness; if (line_width < 0) line_width = -line_width; line_width_and_scale = line_width * (double)int2fixed(1); if (is_fzero(line_width)) always_thin = true; else { float xa, ya; switch (orient) { case orient_portrait: xa = xx, ya = yy; goto sat; case orient_landscape: xa = xy, ya = yx; sat: if (xa < 0) xa = -xa; if (ya < 0) ya = -ya; always_thin = (max(xa, ya) * line_width < 0.5); if (!always_thin && uniform) { /* Precompute a value we'll need later. */ device_line_width_scale = line_width_and_scale * xa; } break; default: { /* The check is more complicated, but it's worth it. */ /* Compute radii of the transformed round brush. */ /* Let x = [a, sqrt(1-a^2)]' radius^2 is an extremum of : rr(a)=(CTM*x)^2 = (a*xx + sqrt(1 - a^2)*xy)^2 + (a*yx + sqrt(1 - a^2)*yy)^2 With solving D(rr(a),a)==0, got : max_rr = (xx^2 + xy^2 + yx^2 + yy^2 + sqrt(((xy + yx)^2 + (xx - yy)^2)*((xy - yx)^2 + (xx + yy)^2)))/2. r = sqrt(max_rr); Well we could use eigenvalues of the quadratic form, but it gives same result with a bigger calculus. */ double max_rr = ((double)(xx*xx + xy*xy + yx*yx + yy*yy) + sqrt((double)((xy + yx)*(xy + yx) + (xx - yy)*(xx - yy)) * ((xy - yx)*(xy - yx) + (xx + yy)*(xx + yy)) ) )/2; always_thin = max_rr * line_width * line_width < 0.25; } } } if_debug7m('o', ppath->memory, "[o]ctm=(%g,%g,%g,%g,%g,%g) thin=%d\n", xx, xy, yx, yy, pgs->ctm.tx, pgs->ctm.ty, always_thin); if (device_dot_length != 0) { /* * Compute the dot length in device space. We can't do this * quite right for non-uniform coordinate systems; too bad. */ gs_matrix mat; const gs_matrix *pmat; if (pgs_lp->dot_length_absolute) { gs_deviceinitialmatrix(pdev, &mat); pmat = &mat; } else pmat = (const gs_matrix *)&pgs->ctm; device_dot_length *= fabs(pmat->xy) + fabs(pmat->yy); } /* Start by flattening the path. We should do this on-the-fly.... */ if (!gx_path_has_curves(ppath) && !gx_path_has_long_segments(ppath)) { /* don't need to flatten */ if (!ppath->first_subpath) return 0; spath = ppath; } else { gx_path_init_local(&fpath, ppath->memory); if ((code = gx_path_add_flattened_for_stroke(ppath, &fpath, params->flatness, pgs)) < 0 ) return code; spath = &fpath; } if (dash_count) { float max_dash_len = 0; float expand_squared; int i; float adjust = (float)pgs->fill_adjust.x; if (adjust > (float)pgs->fill_adjust.y) adjust = (float)pgs->fill_adjust.y; for (i = 0; i < dash_count; i++) { if (max_dash_len < pgs_lp->dash.pattern[i]) max_dash_len = pgs_lp->dash.pattern[i]; } expand_squared = pgs->ctm.xx * pgs->ctm.yy - pgs->ctm.xy * pgs->ctm.yx; if (expand_squared < 0) expand_squared = -expand_squared; expand_squared *= max_dash_len * max_dash_len; /* Wide lines in curves can show dashes up, so fudge to allow for * this. */ if (pgs->line_params.half_width > 1) adjust /= pgs->line_params.half_width; if (expand_squared*65536.0f >= (float)(adjust*adjust)) { gx_path_init_local(&dpath, ppath->memory); code = gx_path_add_dash_expansion(spath, &dpath, pgs); if (code < 0) goto exf; spath = &dpath; } else { dash_count = 0; } } if (to_path == 0) { /* We might try to defer this if it's expensive.... */ to_path = &stroke_path_body; gx_path_init_local(&stroke_path_body, ppath->memory); } if (line_proc == stroke_add_fast) { to_path_reverse = &stroke_path_reverse; gx_path_init_local(&stroke_path_reverse, ppath->memory); } for (psub = spath->first_subpath; psub != 0;) { int index = 0; const segment *pseg = (const segment *)psub; fixed x = pseg->pt.x; fixed y = pseg->pt.y; bool is_closed = ((const subpath *)pseg)->is_closed; partial_line pl, pl_prev, pl_first; bool zero_length = true; int pseg_notes = pseg->notes; flags = nf_all_from_arc; /* Run through each segment in the current path, drawing each segment * delayed by 1 - that is, when we're looking at segment n, we draw * (or not) segment n-1. This delay allows us to always know whether * to join or cap the line. */ while ((pseg = pseg->next) != 0 && pseg->type != s_start ) { /* Compute the width parameters in device space. */ /* We work with unscaled values, for speed. */ fixed sx, udx, sy, udy; bool is_dash_segment; pseg_notes = pseg->notes; d2:is_dash_segment = false; d1:if (pseg->type == s_dash) { dash_segment *pd = (dash_segment *)pseg; sx = pd->pt.x; sy = pd->pt.y; udx = pd->tangent.x; udy = pd->tangent.y; is_dash_segment = true; } else if (pseg->type == s_gap) { sx = pseg->pt.x; sy = pseg->pt.y; udx = sx - x; udy = sy - y; is_dash_segment = true; } else { sx = pseg->pt.x; sy = pseg->pt.y; udx = sx - x; udy = sy - y; } zero_length &= ((udx | udy) == 0); pl.o.p.x = x, pl.o.p.y = y; d:flags = (((pseg_notes & sn_not_first) ? ((flags & nf_all_from_arc) | nf_some_from_arc) : 0) | ((pseg_notes & sn_dash_head) ? nf_dash_head : 0) | ((pseg_notes & sn_dash_tail) ? nf_dash_tail : 0) | (flags & ~nf_all_from_arc)); pl.e.p.x = sx, pl.e.p.y = sy; if (!(udx | udy) || pseg->type == s_dash || pseg->type == s_gap) { /* degenerate or short */ /* * If this is the first segment of the subpath, * check the entire subpath for degeneracy. * Otherwise, ignore the degenerate segment. */ if (index != 0 && pseg->type != s_dash && pseg->type != s_gap) { if (pseg->next == NULL || pseg->next->type == s_start) continue; pseg = pseg->next; /* We're skipping a degenerate path segment; if it was * labelled as being the first from a curve, then make * sure the one we're skipping to is also labelled as * being the first from a curve, otherwise we can get * improper joins being used. See Bug 696466. */ pseg_notes = (((pseg_notes & sn_not_first) == 0) ? (pseg->notes & ~sn_not_first) : pseg->notes); goto d2; } /* Check for a degenerate subpath. */ while ((pseg = pseg->next) != 0 && pseg->type != s_start ) { if (is_dash_segment) break; if (pseg->type == s_dash || pseg->type == s_gap) goto d1; sx = pseg->pt.x, udx = sx - x; sy = pseg->pt.y, udy = sy - y; if (udx | udy) { zero_length = false; goto d; } } if (pgs_lp->dot_length == 0 && pgs_lp->start_cap != gs_cap_round && pgs_lp->end_cap != gs_cap_round && !is_dash_segment) { /* From PLRM, stroke operator : If a subpath is degenerate (consists of a single-point closed path or of two or more points at the same coordinates), stroke paints it only if round line caps have been specified */ break; } /* * If the subpath is a dash, take the orientation from the dash segment. * Otherwise orient the dot according to the previous segment if * any, or else the next segment if any, or else * according to the specified dot orientation. */ { /* When passing here, either pseg == NULL or it points to the start of the next subpaph. So we can't use pseg for determining the segment direction. In same time, psub->last may help, so use it. */ const segment *end = psub->last; if (is_dash_segment) { /* Nothing. */ } else if (end != 0 && (end->pt.x != x || end->pt.y != y)) sx = end->pt.x, sy = end->pt.y, udx = sx - x, udy = sy - y; } /* * Compute the properly oriented dot length, and then * draw the dot like a very short line. */ if ((udx | udy) == 0) { if (is_fzero(pgs_lp->dot_orientation.xy)) { /* Portrait orientation, dot length = X */ udx = fixed_1; } else { /* Landscape orientation, dot length = Y */ udy = fixed_1; } } if (sx == x && sy == y && (pseg == NULL || pseg->type == s_start)) { double scale = device_dot_length / hypot((double)udx, (double)udy); fixed udx1, udy1; /* * If we're using butt caps, make sure the "line" is * long enough to show up. * Don't apply this with always_thin, becase * draw thin line always rounds the length up. */ if (!always_thin && (pgs_lp->start_cap == gs_cap_butt || pgs_lp->end_cap == gs_cap_butt || pgs_lp->dash_cap == gs_cap_butt)) { fixed dmax = max(any_abs(udx), any_abs(udy)); if (dmax * scale < fixed_1) scale = (float)fixed_1 / dmax; } udx1 = (fixed) (udx * scale); udy1 = (fixed) (udy * scale); sx = x + udx1; sy = y + udy1; } /* * Back up 1 segment to keep the bookkeeping straight. */ pseg = (pseg != 0 ? pseg->prev : psub->last); if (!is_dash_segment) goto d; pl.e.p.x = sx; pl.e.p.y = sy; } pl.vector.x = udx; pl.vector.y = udy; if (always_thin) { pl.e.cdelta.x = pl.e.cdelta.y = 0; pl.width.x = pl.width.y = 0; pl.thin = true; } else { if (uniform != 0) { /* We can save a lot of work in this case. */ /* We know orient != orient_other. */ double dpx = udx, dpy = udy; double wl = device_line_width_scale / hypot(dpx, dpy); pl.e.cdelta.x = (fixed) (dpx * wl); pl.e.cdelta.y = (fixed) (dpy * wl); /* The width is the cap delta rotated by */ /* 90 degrees. */ if (initial_matrix_reflected) pl.width.x = pl.e.cdelta.y, pl.width.y = -pl.e.cdelta.x; else pl.width.x = -pl.e.cdelta.y, pl.width.y = pl.e.cdelta.x; pl.thin = false; /* if not always_thin, */ /* then never thin. */ } else { gs_point dpt; /* unscaled */ float wl; code = gs_gstate_idtransform(pgs, (float)udx, (float)udy, &dpt); if (code < 0) { dpt.x = 0; dpt.y = 0; /* Swallow the error */ code = 0; } else { wl = line_width_and_scale / hypot(dpt.x, dpt.y); /* Construct the width vector in */ /* user space, still unscaled. */ dpt.x *= wl; dpt.y *= wl; } /* * We now compute both perpendicular * and (optionally) parallel half-widths, * as deltas in device space. We use * a fixed-point, unscaled version of * gs_dtransform. The second computation * folds in a 90-degree rotation (in user * space, before transforming) in the * direction that corresponds to counter- * clockwise in device space. */ pl.e.cdelta.x = (fixed) (dpt.x * xx); pl.e.cdelta.y = (fixed) (dpt.y * yy); if (orient != orient_portrait) pl.e.cdelta.x += (fixed) (dpt.y * yx), pl.e.cdelta.y += (fixed) (dpt.x * xy); if (!reflected ^ initial_matrix_reflected) dpt.x = -dpt.x, dpt.y = -dpt.y; pl.width.x = (fixed) (dpt.y * xx), pl.width.y = -(fixed) (dpt.x * yy); if (orient != orient_portrait) pl.width.x -= (fixed) (dpt.x * yx), pl.width.y += (fixed) (dpt.y * xy); pl.thin = width_is_thin(&pl); } if (!pl.thin) { if (index) dev->sgr.stroke_stored = false; adjust_stroke(dev, &pl, pgs, false, (pseg->prev == 0 || pseg->prev->type == s_start) && (pseg->next == 0 || pseg->next->type == s_start) && (zero_length || !is_closed), COMBINE_FLAGS(flags)); compute_caps(&pl); } } if (index++) { gs_line_join join = (pseg_notes & not_first ? curve_join : pgs_lp->join); int first; pl_ptr lptr; bool ensure_closed; if (join == gs_join_none) { /* Fake the end of a subpath so we get */ /* caps instead of joins. */ first = 0; lptr = 0; index = 1; } else { first = (is_closed ? 1 : index - 2); lptr = &pl; } #ifdef AVOID_JOINING_TO_DASH_GAPS if (is_dash_segment) /* Never join to a dash segment */ lptr = NULL; #endif if (pseg->type == s_gap) { lptr = NULL; /* We are always drawing one line segment behind, so make * sure we don't draw the next one. */ index = 0; } ensure_closed = ((to_path == &stroke_path_body && lop_is_idempotent(pgs->log_op)) || (lptr == NULL ? true : lptr->thin)); /* Draw the PREVIOUS line segment, joining it to lptr (or * capping if lptr == NULL. */ code = (*line_proc) (to_path, to_path_reverse, ensure_closed, first, &pl_prev, lptr, pdevc, dev, pgs, params, &cbox, uniform, join, initial_matrix_reflected, COMBINE_FLAGS(flags)); if (code < 0) goto exit; FILL_STROKE_PATH(pdev, always_thin, pcpath, false); } else if (pseg->type == s_gap) { /* If this segment is a gap, then we don't want to draw it * next time! */ index = 0; } else pl_first = pl; pl_prev = pl; x = sx, y = sy; flags = (flags<<4) | nf_all_from_arc; } if (index) { /* If closed, join back to start, else cap. */ segment_notes notes = (pseg == 0 ? (const segment *)spath->first_subpath : pseg)->notes; gs_line_join join = (notes & not_first ? curve_join : pgs_lp->join); gs_line_cap cap; /* For some reason, the Borland compiler requires the cast */ /* in the following statement. */ pl_ptr lptr = (!is_closed || join == gs_join_none || zero_length ? (pl_ptr) 0 : (pl_ptr) & pl_first); #ifdef AVOID_JOINING_TO_DASH_GAPS if (lptr && psub->type == s_dash) lptr = NULL; #endif /* If the subpath starts with a gap, then cap, don't join! */ if (lptr && psub->type == s_start && psub->next && psub->next->type == s_gap) lptr = NULL; flags = (((notes & sn_not_first) ? ((flags & nf_all_from_arc) | nf_some_from_arc) : 0) | ((notes & sn_dash_head) ? nf_dash_head : 0) | ((notes & sn_dash_tail) ? nf_dash_tail : 0) | (flags & ~nf_all_from_arc)); code = (*line_proc) (to_path, to_path_reverse, true, index - 1, &pl_prev, lptr, pdevc, dev, pgs, params, &cbox, uniform, join, initial_matrix_reflected, COMBINE_FLAGS(flags)); if (code < 0) goto exit; FILL_STROKE_PATH(pdev, always_thin, pcpath, false); cap = ((flags & nf_prev_dash_head) ? pgs_lp->start_cap : pgs_lp->dash_cap); if (traditional && lptr == 0 && cap != gs_cap_butt) { /* Create the initial cap at last. */ code = stroke_add_initial_cap_compat(to_path, &pl_first, index == 1, pdevc, dev, pgs); if (code < 0) goto exit; FILL_STROKE_PATH(pdev, always_thin, pcpath, false); } } psub = (const subpath *)pseg; } if (to_path_reverse != NULL) code = gx_join_path_and_reverse(to_path, to_path_reverse); FILL_STROKE_PATH(pdev, always_thin, pcpath, true); exit: if (dev == (gx_device *)&cdev) cdev.target->sgr = cdev.sgr; if (to_path == &stroke_path_body) gx_path_free(&stroke_path_body, "gx_stroke_path_only error"); /* (only needed if error) */ if (to_path_reverse == &stroke_path_reverse) gx_path_free(&stroke_path_reverse, "gx_stroke_path_only error"); exf: if (dash_count) gx_path_free(&dpath, "gx_stroke_path exit(dash path)"); if (ppath->curve_count) gx_path_free(&fpath, "gx_stroke_path exit(flattened path)"); return code; } int gx_stroke_path_only(gx_path * ppath, gx_path * to_path, gx_device * pdev, const gs_gstate * pgs, const gx_stroke_params * params, const gx_device_color * pdevc, const gx_clip_path * pcpath) { return gx_stroke_path_only_aux(ppath, to_path, pdev, pgs, params, pdevc, pcpath); } /* ------ Internal routines ------ */ /* * Test whether a line is thin, i.e., whether the half-width, measured * perpendicular to the line in device space, is less than 0.5 pixel. * Unfortunately, the width values we computed are perpendicular to the * line in *user* space, so we may have to do some extra work. */ static bool width_is_thin(pl_ptr plp) { fixed dx, dy, wx = plp->width.x, wy = plp->width.y; /* If the line is horizontal or vertical, things are easy. */ if ((dy = plp->vector.y) == 0) return any_abs(wy) < fixed_half; if ((dx = plp->vector.x) == 0) return any_abs(wx) < fixed_half; /* For the longest time, we used to have a test here that * attempted to trivially accept diagonal lines as being * thin based on the components of the perpendicular * width vector in device space as both being less than 0.5. * Bug 702196 showed some examples where this was clearly * wrong. * * The cause for this bug was that the 0.5 figure was wrong. * For the point to be less than 1/2 a pixel perpendicular * distant from the line, we'd need x^2 + y^2 < .5^2. * For a 45 degree line, that'd be 2(x^2) < 1/4 = x^2 < 1/8 * or x < sqr(1/8). 45 degree line is the "worst case", so * if both horizontal and vertical widths are less than * sqr(1/8), the line is thin. sqr(1/8) = 0.35355339059. * So, we should be using sqr(1/8) rather than 0.5. * * Fixing this did indeed produce many many progressions, * but left just the odd file still showing problems. * * Further investigations show that those cases were due to * the use of "non-uniform" scaling matrices, for example * (83 0 0 51 0 0). With such matrices, it's possible for * nearly horizontal lines to be thin, but nearly vertical * ones to be thick (or vice versa). Having the style of * line "pop" between thick and thin in a single stroke * looks very noticeable. * * We could change the trivial optimisation below to only * apply in the 'uniform' case, but that would never actually * trigger (as tested on the cluster), because all such * cases are caught by the "always_thin" condition in the * caller. * * Just removing the trivial test and leaving the 'complicated' * test below us would leave us vulnerable to "popping", * so we disable both. In practice this makes no difference * to the number of tests showing diffs in the cluster. */ #if 0 /* DISABLED TEST, see above */ { /* thin_threshold = fixed sqr(1/8) - see above. */ const fixed thin_threshold = float2fixed(0.35355339059f); if (any_abs(wx) < thin_threshold && any_abs(wy) < thin_threshold) return true; } /* * We have to do this the hard way, by actually computing the * perpendicular distance. The distance from the point (U,V) * from a line from (0,0) to (C,D) is * abs(C*V - D*U) / sqrt(C^2 + D^2) * In this case, (U,V) is plp->width, and (C,D) is (dx,dy). */ { double C = dx, D = dy; double num = C * wy - D * wx; double denom = hypot(C, D); /* both num and denom are scaled by fixed_scale^2, */ /* so we don't need to do any de-scaling for the test. */ return fabs(num) < denom * 0.5; } #else return false; #endif } /* Adjust the endpoints and width of a stroke segment along a specified axis */ static void adjust_stroke_transversal(pl_ptr plp, const gs_gstate * pgs, bool thin, bool horiz) { fixed *pw; fixed *pov; fixed *pev; fixed w, w2; fixed adj2; if (horiz) { /* More horizontal stroke */ pw = &plp->width.y, pov = &plp->o.p.y, pev = &plp->e.p.y; adj2 = STROKE_ADJUSTMENT(thin, pgs, y) << 1; } else { /* More vertical stroke */ pw = &plp->width.x, pov = &plp->o.p.x, pev = &plp->e.p.x; adj2 = STROKE_ADJUSTMENT(thin, pgs, x) << 1; } /* Round the larger component of the width up or down, */ /* whichever way produces a result closer to the correct width. */ /* Note that just rounding the larger component */ /* may not produce the correct result. */ w = *pw; if (w > 0) w2 = fixed_rounded(w << 1); /* full line width */ else w2 = -fixed_rounded(-w << 1); /* full line width */ if (w2 == 0 && *pw != 0) { /* Make sure thin lines don't disappear. */ w2 = (*pw < 0 ? -fixed_1 + adj2 : fixed_1 - adj2); *pw = arith_rshift_1(w2); } /* Only adjust the endpoints if the line is horizontal or vertical. */ if (*pov == *pev) { /* We're going to round the endpoint coordinates, so */ /* take the fill adjustment into account now. */ if (w >= 0) w2 += adj2; else w2 = adj2 - w2; if (w2 & fixed_1) /* odd width, move to half-pixel */ *pov = *pev = fixed_floor(*pov) + fixed_half; else /* even width, move to pixel */ *pov = *pev = fixed_rounded(*pov); } } static void adjust_stroke_longitude(pl_ptr plp, const gs_gstate * pgs, bool thin, bool horiz, gs_line_cap start_cap, gs_line_cap end_cap) { fixed *pow = (horiz ? &plp->o.p.y : &plp->o.p.x); fixed *pew = (horiz ? &plp->e.p.y : &plp->e.p.x); /* Only adjust the endpoints if the line is horizontal or vertical. Debugged with pdfwrite->ppmraw 72dpi file2.pdf */ if (*pow == *pew) { fixed *pov = (horiz ? &plp->o.p.x : &plp->o.p.y); fixed *pev = (horiz ? &plp->e.p.x : &plp->e.p.y); fixed length = any_abs(*pov - *pev); fixed length_r, length_r_2; fixed mv = (*pov + *pev) / 2, mv_r; fixed adj2 = (horiz ? STROKE_ADJUSTMENT(thin, pgs, x) : STROKE_ADJUSTMENT(thin, pgs, y)) << 1; /* fixme : The best value for adjust_longitude is whether the dash is isolated and doesn't cover entire segment. The current data structure can't pass this info. Therefore we restrict adjust_stroke_longitude with 1 pixel length. */ if (length > fixed_1) /* comparefiles/file2.pdf */ return; if (start_cap == gs_cap_butt || end_cap == gs_cap_butt) { length_r = fixed_rounded(length); if (length_r < fixed_1) length_r = fixed_1; length_r_2 = length_r / 2; } else { /* Account width for proper placing cap centers. */ fixed width = any_abs(horiz ? plp->width.y : plp->width.x); length_r = fixed_rounded(length + width * 2 + adj2); length_r_2 = fixed_rounded(length) / 2; } if (length_r & fixed_1) mv_r = fixed_floor(mv) + fixed_half; else mv_r = fixed_floor(mv); if (*pov < *pev) { *pov = mv_r - length_r_2; *pev = mv_r + length_r_2; } else { *pov = mv_r + length_r_2; *pev = mv_r - length_r_2; } } } /* Adjust the endpoints and width of a stroke segment */ /* to achieve more uniform rendering. */ /* Only o.p, e.p, e.cdelta, and width have been set. */ static void adjust_stroke(gx_device *dev, pl_ptr plp, const gs_gstate * pgs, bool thin, bool adjust_longitude, note_flags flags) { bool horiz, adjust = true; gs_line_cap start_cap = (flags & nf_dash_head ? pgs->line_params.dash_cap : pgs->line_params.start_cap); gs_line_cap end_cap = (flags & nf_dash_tail ? pgs->line_params.dash_cap : pgs->line_params.end_cap); /* If stroke_adjustment is disabled, or this isn't a horizontal or * vertical line, then bale. */ if (!pgs->stroke_adjust || (plp->width.x != 0 && plp->width.y != 0)) { dev->sgr.stroke_stored = false; return; /* don't adjust */ } /* Recognizing gradients, which some obsolete software represent as a set of parallel strokes. Such strokes must not be adjusted - bug 687974. */ if (dev->sgr.stroke_stored && (start_cap == gs_cap_butt || end_cap == gs_cap_butt) && dev->sgr.orig[3].x == plp->vector.x && dev->sgr.orig[3].y == plp->vector.y) { /* Parallel. */ if ((int64_t)(plp->o.p.x - dev->sgr.orig[0].x) * plp->vector.x == (int64_t)(plp->o.p.y - dev->sgr.orig[0].y) * plp->vector.y && (int64_t)(plp->e.p.x - dev->sgr.orig[1].x) * plp->vector.x == (int64_t)(plp->e.p.y - dev->sgr.orig[1].y) * plp->vector.y) { /* Transversal shift. */ if (any_abs(plp->o.p.x - dev->sgr.orig[0].x) <= any_abs(plp->width.x + dev->sgr.orig[2].x) && any_abs(plp->o.p.y - dev->sgr.orig[0].y) <= any_abs(plp->width.y + dev->sgr.orig[2].y) && any_abs(plp->e.p.x - dev->sgr.orig[1].x) <= any_abs(plp->width.x + dev->sgr.orig[2].x) && any_abs(plp->e.p.y - dev->sgr.orig[1].y) <= any_abs(plp->width.y + dev->sgr.orig[2].y)) { /* The strokes were contacting or overlapping. */ if (any_abs(plp->o.p.x - dev->sgr.orig[0].x) >= any_abs(plp->width.x + dev->sgr.orig[2].x) / 2 && any_abs(plp->o.p.y - dev->sgr.orig[0].y) >= any_abs(plp->width.y + dev->sgr.orig[2].y) / 2 && any_abs(plp->e.p.x - dev->sgr.orig[1].x) >= any_abs(plp->width.x + dev->sgr.orig[2].x) / 2 && any_abs(plp->e.p.y - dev->sgr.orig[1].y) >= any_abs(plp->width.y + dev->sgr.orig[2].y) / 2) { /* The strokes were not much overlapping. */ if (!(any_abs(plp->o.p.x - dev->sgr.adjusted[0].x) <= any_abs(plp->width.x + dev->sgr.adjusted[2].x) && any_abs(plp->o.p.y - dev->sgr.adjusted[0].y) <= any_abs(plp->width.y + dev->sgr.adjusted[2].y) && any_abs(plp->e.p.x - dev->sgr.adjusted[1].x) <= any_abs(plp->width.x + dev->sgr.adjusted[2].x) && any_abs(plp->e.p.y - dev->sgr.adjusted[1].y) <= any_abs(plp->width.y + dev->sgr.adjusted[2].y))) { /* they became not contacting. We should not have adjusted the last stroke. Since if we did, lets change the current one to restore the contact, so that we don't leave gaps when rasterising. See bug 687974. */ fixed delta_w_x = (dev->sgr.adjusted[2].x - dev->sgr.orig[2].x); fixed delta_w_y = (dev->sgr.adjusted[2].y - dev->sgr.orig[2].y); fixed shift_o_x = (dev->sgr.adjusted[0].x - dev->sgr.orig[0].x); fixed shift_o_y = (dev->sgr.adjusted[0].y - dev->sgr.orig[0].y); fixed shift_e_x = (dev->sgr.adjusted[1].x - dev->sgr.orig[1].x); /* Must be same, but we prefer clarity. */ fixed shift_e_y = (dev->sgr.adjusted[1].y - dev->sgr.orig[1].y); if (plp->o.p.x < dev->sgr.orig[0].x || (plp->o.p.x == dev->sgr.orig[0].x && plp->o.p.y < dev->sgr.orig[0].y)) { /* Left contact, adjust to keep the contact. */ if_debug4m('O', dev->memory, "[O]don't adjust {{%f,%f},{%f,%f}}\n", fixed2float(plp->o.p.x), fixed2float(plp->o.p.y), fixed2float(plp->e.p.x), fixed2float(plp->e.p.y)); plp->width.x += (shift_o_x - delta_w_x) / 2; plp->width.y += (shift_o_y - delta_w_y) / 2; plp->o.p.x += (shift_o_x - delta_w_x) / 2; plp->o.p.y += (shift_o_y - delta_w_y) / 2; plp->e.p.x += (shift_e_x - delta_w_x) / 2; plp->e.p.y += (shift_e_y - delta_w_y) / 2; adjust = false; } else { /* Right contact, adjust to keep the contact. */ if_debug4m('O', dev->memory, "[O]don't adjust {{%f,%f},{%f,%f}}\n", fixed2float(plp->o.p.x), fixed2float(plp->o.p.y), fixed2float(plp->e.p.x), fixed2float(plp->e.p.y)); plp->width.x -= (shift_o_x + delta_w_x) / 2; plp->width.y -= (shift_o_y + delta_w_y) / 2; plp->o.p.x += (shift_o_x + delta_w_x) / 2; plp->o.p.y += (shift_o_y + delta_w_y) / 2; plp->e.p.x += (shift_e_x + delta_w_x) / 2; plp->e.p.y += (shift_e_y + delta_w_y) / 2; adjust = false; } } } } } } if ((start_cap == gs_cap_butt) || (end_cap == gs_cap_butt)) { dev->sgr.stroke_stored = true; dev->sgr.orig[0] = plp->o.p; dev->sgr.orig[1] = plp->e.p; dev->sgr.orig[2] = plp->width; dev->sgr.orig[3] = plp->vector; } else dev->sgr.stroke_stored = false; if (adjust) { horiz = (any_abs(plp->width.x) <= any_abs(plp->width.y)); adjust_stroke_transversal(plp, pgs, thin, horiz); if (adjust_longitude) adjust_stroke_longitude(plp, pgs, thin, horiz, start_cap, end_cap); } if ((start_cap == gs_cap_butt) || (end_cap == gs_cap_butt)) { dev->sgr.adjusted[0] = plp->o.p; dev->sgr.adjusted[1] = plp->e.p; dev->sgr.adjusted[2] = plp->width; dev->sgr.adjusted[3] = plp->vector; } } /* Compute the intersection of two lines. This is a messy algorithm */ /* that somehow ought to be useful in more places than just here.... */ /* If the lines are (nearly) parallel, return -1 without setting *pi; */ /* otherwise, return 0 if the intersection is beyond *pp1 and *pp2 in */ /* the direction determined by *pd1 and *pd2, and 1 otherwise. */ static int line_intersect( p_ptr pp1, /* point on 1st line */ p_ptr pd1, /* slope of 1st line (dx,dy) */ p_ptr pp2, /* point on 2nd line */ p_ptr pd2, /* slope of 2nd line */ p_ptr pi) { /* return intersection here */ /* We don't have to do any scaling, the factors all work out right. */ double u1 = pd1->x, v1 = pd1->y; double u2 = pd2->x, v2 = pd2->y; double denom = u1 * v2 - u2 * v1; double xdiff = pp2->x - pp1->x; double ydiff = pp2->y - pp1->y; double f1; double max_result = any_abs(denom) * (double)max_fixed; #if defined(DEBUG) && !defined(GS_THREADSAFE) if (gs_debug_c('O')) { dlprintf4("[o]Intersect %f,%f(%f/%f)", fixed2float(pp1->x), fixed2float(pp1->y), fixed2float(pd1->x), fixed2float(pd1->y)); dlprintf4(" & %f,%f(%f/%f),\n", fixed2float(pp2->x), fixed2float(pp2->y), fixed2float(pd2->x), fixed2float(pd2->y)); dlprintf3("\txdiff=%f ydiff=%f denom=%f ->\n", xdiff, ydiff, denom); } #endif /* Check for degenerate result. */ if (any_abs(xdiff) >= max_result || any_abs(ydiff) >= max_result) { /* The lines are nearly parallel, */ /* or one of them has zero length. Punt. */ if_debug0('O', "\tdegenerate!\n"); return -1; } f1 = (v2 * xdiff - u2 * ydiff) / denom; pi->x = pp1->x + (fixed) (f1 * u1); pi->y = pp1->y + (fixed) (f1 * v1); if_debug2('O', "\t%f,%f\n", fixed2float(pi->x), fixed2float(pi->y)); return (f1 >= 0 && (v1 * xdiff >= u1 * ydiff ? denom >= 0 : denom < 0) ? 0 : 1); } /* Set up the width and delta parameters for a thin line. */ /* We only approximate the width and height. */ static void set_thin_widths(register pl_ptr plp) { fixed dx = plp->e.p.x - plp->o.p.x, dy = plp->e.p.y - plp->o.p.y; #define TRSIGN(v, c) ((v) >= 0 ? (c) : -(c)) if (any_abs(dx) > any_abs(dy)) { plp->width.x = plp->e.cdelta.y = 0; plp->width.y = plp->e.cdelta.x = TRSIGN(dx, fixed_half); } else { plp->width.y = plp->e.cdelta.x = 0; plp->width.x = -(plp->e.cdelta.y = TRSIGN(dy, fixed_half)); } #undef TRSIGN } /* Draw a line on the device. */ /* Treat no join the same as a bevel join. */ /* rpath should always be NULL, hence ensure_closed can be ignored */ static int stroke_fill(gx_path * ppath, gx_path * rpath, bool ensure_closed, int first, register pl_ptr plp, pl_ptr nplp, const gx_device_color * pdevc, gx_device * dev, const gs_gstate * pgs, const gx_stroke_params * params, const gs_fixed_rect * pbbox, int uniform, gs_line_join join, bool reflected, note_flags flags) { const fixed lix = plp->o.p.x; const fixed liy = plp->o.p.y; const fixed litox = plp->e.p.x; const fixed litoy = plp->e.p.y; /* assert(lop_is_idempotent(pgs->log_op)); */ if (plp->thin) { /* Minimum-width line, don't have to be careful with caps/joins. */ return (*dev_proc(dev, draw_thin_line))(dev, lix, liy, litox, litoy, pdevc, pgs->log_op, pgs->fill_adjust.x, pgs->fill_adjust.y); } /* Check for being able to fill directly. */ { const gx_line_params *pgs_lp = gs_currentlineparams_inline(pgs); gs_line_cap start_cap = (flags & nf_dash_head ? pgs_lp->dash_cap : pgs_lp->start_cap); gs_line_cap end_cap = (flags & nf_dash_tail ? pgs_lp->dash_cap : pgs_lp->end_cap); if (first != 0) start_cap = gs_cap_butt; if (nplp != 0) end_cap = gs_cap_butt; if (!plp->thin && (nplp == 0 || !nplp->thin) && (start_cap == gs_cap_butt || start_cap == gs_cap_square) && (end_cap == gs_cap_butt || end_cap == gs_cap_square) && (join == gs_join_bevel || join == gs_join_miter || join == gs_join_none) && (pgs->fill_adjust.x | pgs->fill_adjust.y) == 0 ) { gs_fixed_point points[6]; int npoints, code; fixed ax, ay, bx, by; npoints = cap_points(start_cap, &plp->o, points); if (nplp == 0) code = cap_points(end_cap, &plp->e, points + npoints); else code = line_join_points(pgs_lp, plp, nplp, points + npoints, (uniform ? (gs_matrix *) 0 : &ctm_only(pgs)), join, reflected); if (code < 0) goto general; /* Make sure the parallelogram fill won't overflow. */ #define SUB_OVERFLOWS(r, u, v)\ (((r = u - v) ^ u) < 0 && (u ^ v) < 0) if (SUB_OVERFLOWS(ax, points[0].x, points[1].x) || SUB_OVERFLOWS(ay, points[0].y, points[1].y) || SUB_OVERFLOWS(bx, points[2].x, points[1].x) || SUB_OVERFLOWS(by, points[2].y, points[1].y) ) goto general; #undef SUB_OVERFLOWS if (nplp != 0) { if (join == gs_join_miter) { /* Make sure we have a bevel and not a miter. */ if (!(points[2].x == plp->e.co.x && points[2].y == plp->e.co.y && points[5].x == plp->e.ce.x && points[5].y == plp->e.ce.y) ) goto fill; } { const gs_fixed_point *bevel = points + 2; /* Identify which 3 points define the bevel triangle. */ if (points[3].x == nplp->o.p.x && points[3].y == nplp->o.p.y ) ++bevel; /* Fill the bevel. */ code = (*dev_proc(dev, fill_triangle)) (dev, bevel->x, bevel->y, bevel[1].x - bevel->x, bevel[1].y - bevel->y, bevel[2].x - bevel->x, bevel[2].y - bevel->y, pdevc, pgs->log_op); if (code < 0) return code; } } /* Fill the body of the stroke. */ return (*dev_proc(dev, fill_parallelogram)) (dev, points[1].x, points[1].y, ax, ay, bx, by, pdevc, pgs->log_op); fill: code = add_points(ppath, points, npoints + code, true); if (code < 0) return code; return gx_path_close_subpath(ppath); } } /* General case: construct a path for the fill algorithm. */ general: return stroke_add(ppath, rpath, ensure_closed, first, plp, nplp, pdevc, dev, pgs, params, pbbox, uniform, join, reflected, flags); } /* Add a segment to the path. This handles all the complex cases. */ static int stroke_add(gx_path * ppath, gx_path * rpath, bool ensure_closed, int first, pl_ptr plp, pl_ptr nplp, const gx_device_color * pdevc, gx_device * dev, const gs_gstate * pgs, const gx_stroke_params * params, const gs_fixed_rect * ignore_pbbox, int uniform, gs_line_join join, bool reflected, note_flags flags) { const gx_line_params *pgs_lp = gs_currentlineparams_inline(pgs); gs_fixed_point points[8]; int npoints; int code; bool moveto_first = true; gs_line_cap start_cap = (flags & nf_dash_head ? pgs_lp->dash_cap : pgs_lp->start_cap); gs_line_cap end_cap = (flags & nf_dash_tail ? pgs_lp->dash_cap : pgs_lp->end_cap); if (plp->thin) { /* We didn't set up the endpoint parameters before, */ /* because the line was thin. Do it now. */ set_thin_widths(plp); adjust_stroke(dev, plp, pgs, true, first == 0 && nplp == 0, flags); compute_caps(plp); } /* Create an initial cap if desired. */ if (first == 0 && start_cap == gs_cap_round) { if ((code = gx_path_add_point(ppath, plp->o.co.x, plp->o.co.y)) < 0 || (code = add_pie_cap(ppath, &plp->o)) < 0) return code; npoints = 0; moveto_first = false; } else { if ((npoints = cap_points((first == 0 ? start_cap : gs_cap_butt), &plp->o, points)) < 0) return npoints; } if (nplp == 0) { /* Add a final cap. */ if (end_cap == gs_cap_round) { ASSIGN_POINT(&points[npoints], plp->e.co); ++npoints; if ((code = add_points(ppath, points, npoints, moveto_first)) < 0) return code; code = add_pie_cap(ppath, &plp->e); goto done; } code = cap_points(end_cap, &plp->e, points + npoints); } else if (nplp->thin) /* no join */ code = cap_points(gs_cap_butt, &plp->e, points + npoints); else if (join == gs_join_round) { ASSIGN_POINT(&points[npoints], plp->e.co); ++npoints; if ((code = add_points(ppath, points, npoints, moveto_first)) < 0) return code; code = add_pie_join(ppath, plp, nplp, reflected, true); goto done; } else if (flags & nf_all_from_arc) { /* If all the segments in 'prev' and 'current' are from a curve * then the join should actually be a round one, because it would * have been round if we had flattened it enough. */ ASSIGN_POINT(&points[npoints], plp->e.co); ++npoints; if ((code = add_points(ppath, points, npoints, moveto_first)) < 0) return code; code = add_pie_join(ppath, plp, nplp, reflected, false); goto done; } else /* non-round join */ code = line_join_points(pgs_lp, plp, nplp, points + npoints, (uniform ? (gs_matrix *) 0 : &ctm_only(pgs)), join, reflected); if (code < 0) return code; code = add_points(ppath, points, npoints + code, moveto_first); done: if (code < 0) return code; if ((flags & nf_some_from_arc) && (!plp->thin) && (nplp != NULL) && (!nplp->thin)) code = join_under_pie(ppath, plp, nplp, reflected); return gx_path_close_subpath(ppath); } /* When painting the 'underjoin' (the 'inside' of a join), we * need to take special care if the curve is particularly wide as * the leading edge of the underside of the first stroked segment * may be beyond the leading edge of the underside of the second * stroked segment. Similarly, the trailing edge of the second * stroked segment may be behing the trailing edge of the first * stroked segment. We detect those cases here. * * We detect the first case by projecting plp.width onto nplp.vector. * If the projected vector is longer then nplp.vector, we have a * problem. * * len_vector_squared = nplp.vector.x * nplp.vector.x + nplp.vector.y * nplp.nvector.y * len_vector = sqr(len_vector_squared) * len_projection_unnormalised = plp.width.x * nplp.vector.x + plp.width.y * nplp.vector.y * len_projection = len_projection_unnormalised / len_vector * * len_projection > len_vector === len_projection_unnormalised > len_vector * len_vector * === len_projection_unnormalised > len_vector_squared */ #ifdef SLOWER_BUT_MORE_ACCURATE_STROKING static bool wide_underjoin(pl_ptr plp, pl_ptr nplp) { double h_squared = (double)nplp->vector.x * nplp->vector.x + (double)nplp->vector.y * nplp->vector.y; double dot = (double)plp->width.x * nplp->vector.x + (double)plp->width.y * nplp->vector.y; if (dot < 0) dot = -dot; if (dot > h_squared) return 1; h_squared = (double)plp->vector.x * plp->vector.x + (double)plp->vector.y * plp->vector.y; dot = (double)nplp->width.x * plp->vector.x + (double)nplp->width.y * plp->vector.y; if (dot < 0) dot = -dot; if (dot > h_squared) return 1; return 0; } #endif static int check_miter(const gx_line_params * pgs_lp, pl_ptr plp, pl_ptr nplp, const gs_matrix * pmat, p_ptr outp, p_ptr np, p_ptr mpt, bool ccw0) { /* * Check whether a miter join is appropriate. * Let a, b be the angles of the two lines. * We check tan(a-b) against the miter_check * by using the following formula: * If tan(a)=u1/v1 and tan(b)=u2/v2, then * tan(a-b) = (u1*v2 - u2*v1) / (u1*u2 + v1*v2). * * We can do all the computations unscaled, * because we're only concerned with ratios. * However, if we have a non-uniform coordinate * system (indicated by pmat != 0), we must do the * computations in user space. */ float check; double u1, v1, u2, v2; double num, denom; int code; /* * Don't bother with the miter check if the two * points to be joined are very close together, * namely, in the same square half-pixel. */ if (fixed2long(outp->x << 1) == fixed2long(np->x << 1) && fixed2long(outp->y << 1) == fixed2long(np->y << 1)) return 1; check = pgs_lp->miter_check; u1 = plp->vector.y, v1 = plp->vector.x; u2 = -nplp->vector.y, v2 = -nplp->vector.x; if (pmat) { gs_point pt; code = gs_distance_transform_inverse(v1, u1, pmat, &pt); if (code < 0) return code; v1 = pt.x, u1 = pt.y; code = gs_distance_transform_inverse(v2, u2, pmat, &pt); if (code < 0) return code; v2 = pt.x, u2 = pt.y; /* * We need to recompute ccw according to the * relative positions of the lines in user space. * We repeat the computation described above, * using the cdelta values instead of the widths. * Because the definition of ccw above is inverted * from the intuitive one (for historical reasons), * we actually have to do the test backwards. */ ccw0 = v1 * u2 < v2 * u1; #if defined(DEBUG) && !defined(GS_THREADSAFE) { double a1 = atan2(u1, v1), a2 = atan2(u2, v2), dif = a1 - a2; if (dif < 0) dif += 2 * M_PI; else if (dif >= 2 * M_PI) dif -= 2 * M_PI; if (dif != 0 && (dif < M_PI) != ccw0) lprintf8("ccw wrong: tan(a1=%g)=%g/%g, tan(a2=%g)=%g,%g, dif=%g, ccw0=%d\n", a1, u1, v1, a2, u2, v2, dif, ccw0); } #endif } num = u1 * v2 - u2 * v1; denom = u1 * u2 + v1 * v2; /* * We will want either tan(a-b) or tan(b-a) * depending on the orientations of the lines. * Fortunately we know the relative orientations already. */ if (!ccw0) /* have plp - nplp, want vice versa */ num = -num; #if defined(DEBUG) && !defined(GS_THREADSAFE) if (gs_debug_c('O')) { dlprintf4("[o]Miter check: u1/v1=%f/%f, u2/v2=%f/%f,\n", u1, v1, u2, v2); dlprintf3(" num=%f, denom=%f, check=%f\n", num, denom, check); } #endif /* * If we define T = num / denom, then we want to use * a miter join iff arctan(T) >= arctan(check). * We know that both of these angles are in the 1st * or 2nd quadrant, and since arctan is monotonic * within each quadrant, we can do the comparisons * on T and check directly, taking signs into account * as follows: * sign(T) sign(check) atan(T) >= atan(check) * ------- ----------- ---------------------- * + + T >= check * - + true * + - false * - - T >= check */ if (num == 0 && denom == 0) return_error(gs_error_unregistered); /* Must not happen. */ if (denom < 0) num = -num, denom = -denom; /* Now denom >= 0, so sign(num) = sign(T). */ if (check > 0 ? (num < 0 || num >= denom * check) : (num < 0 && num >= denom * check) ) { /* OK to use a miter join. */ gs_fixed_point dirn1, dirn2; dirn1.x = plp->e.cdelta.x; dirn1.y = plp->e.cdelta.y; /* If this direction is small enough that we might have * underflowed and the vector record is suitable for us * to use to calculate a better one, then do so. */ if ((abs(dirn1.x) + abs(dirn1.y) < 16) && ((plp->vector.x != 0) || (plp->vector.y != 0))) { float scale = 65536.0; if (abs(plp->vector.x) > abs(plp->vector.y)) scale /= abs(plp->vector.x); else scale /= abs(plp->vector.y); dirn1.x = (fixed)(plp->vector.x*scale); dirn1.y = (fixed)(plp->vector.y*scale); } dirn2.x = nplp->o.cdelta.x; dirn2.y = nplp->o.cdelta.y; /* If this direction is small enough that we might have * underflowed and the vector record is suitable for us * to use to calculate a better one, then do so. */ if ((abs(dirn2.x) + abs(dirn2.y) < 16) && ((nplp->vector.x != 0) || (nplp->vector.y != 0))) { float scale = 65536.0; if (abs(nplp->vector.x) > abs(nplp->vector.y)) scale /= abs(nplp->vector.x); else scale /= abs(nplp->vector.y); dirn2.x = (fixed)(-nplp->vector.x*scale); dirn2.y = (fixed)(-nplp->vector.y*scale); } if_debug0('O', " ... passes.\n"); /* Compute the intersection of the extended edge lines. */ if (line_intersect(outp, &dirn1, np, &dirn2, mpt) == 0) return 0; } return 1; } /* Add a segment to the path. * This works by crafting 2 paths, one for each edge, that will later be * merged together. */ static int stroke_add_fast(gx_path * ppath, gx_path * rpath, bool ensure_closed, int first, pl_ptr plp, pl_ptr nplp, const gx_device_color * pdevc, gx_device * dev, const gs_gstate * pgs, const gx_stroke_params * params, const gs_fixed_rect * ignore_pbbox, int uniform, gs_line_join join, bool reflected, note_flags flags) { const gx_line_params *pgs_lp = gs_currentlineparams_inline(pgs); gs_fixed_point points[8]; gs_fixed_point rpoints[8]; int npoints = 0; int nrpoints = 0; int code; bool moveto_first = false; bool rmoveto_first = false; gs_line_cap start_cap, end_cap; const gs_matrix *pmat = (uniform ? (const gs_matrix *)NULL : &ctm_only(pgs)); enum { joinsense_cap = 0, joinsense_cw = 1, joinsense_ccw = 2, joinsense_over = 4, joinsense_under = 8, } joinsense = joinsense_cap; if (plp->thin) { /* We didn't set up the endpoint parameters before, */ /* because the line was thin. Do it now. */ set_thin_widths(plp); adjust_stroke(dev, plp, pgs, true, first == 0 && nplp == 0, flags); compute_caps(plp); } start_cap = (flags & nf_dash_head ? pgs_lp->dash_cap : pgs_lp->start_cap); end_cap = (flags & nf_dash_tail ? pgs_lp->dash_cap : pgs_lp->end_cap); /* If we're starting a new rpath here, we need to fake a new cap. * Don't interfere if we would have been doing a cap anyway. */ if (gx_path_is_void(rpath) && (first != 0)) { first = 0; start_cap = gs_cap_butt; end_cap = gs_cap_butt; moveto_first = true; rmoveto_first = true; } if (first == 0) { /* Create an initial cap. */ if (start_cap == gs_cap_round) { if ((code = gx_path_add_point(ppath, plp->o.co.x, plp->o.co.y)) < 0 || (code = add_pie_cap(ppath, &plp->o)) < 0) return code; moveto_first = false; } else { if ((npoints = cap_points(start_cap, &plp->o, points)) < 0) return npoints; moveto_first = true; } rmoveto_first = true; ASSIGN_POINT(&rpoints[0], plp->o.co); nrpoints = 1; } /* Add points to move us along the edges of this stroke */ ASSIGN_POINT(&points [npoints ], plp->e.co); ASSIGN_POINT(&rpoints[nrpoints], plp->e.ce); npoints++; nrpoints++; if (nplp != NULL && !nplp->thin) { /* We need to do a join. What sense is it it? */ double l, r; l = (double)(plp->width.x) /* x1 */ * (nplp->width.y) /* y2 */; r = (double)(nplp->width.x) /* x2 */ * (plp->width.y) /* y1 */; if ((l == r) && (join == gs_join_round)) joinsense = joinsense_cap; else if ((l > r) ^ reflected) joinsense = joinsense_ccw | joinsense_over | joinsense_under; else joinsense = joinsense_cw | joinsense_over | joinsense_under; if (joinsense != joinsense_cap && join == gs_join_miter) { /* We need to do a miter line join. Miters are 'special' * in that we'd like to do them by adjusting the existing * points, rather than adding new ones. */ gs_fixed_point mpt; if (joinsense & joinsense_ccw) { /* Underjoin (in reverse path): * A = plp->o.co, B = plp->e.ce, C = nplp->o.co, D = nplp->e.ce */ double xa = plp->o.co.x, ya = plp->o.co.y; double xb = plp->e.ce.x, yb = plp->e.ce.y; double xc = nplp->o.co.x, yc = nplp->o.co.y; double xd = nplp->e.ce.x, yd = nplp->e.ce.y; double xab = xa-xb, xac = xa-xc, xcd = xc-xd; double yab = ya-yb, yac = ya-yc, ycd = yc-yd; double t_num = xac * ycd - yac * xcd; double t_den = xab * ycd - yab * xcd; code = check_miter(pgs_lp, plp, nplp, pmat, &plp->e.co, &nplp->o.ce, &mpt, true); if (code < 0) return code; if (code == 0) { points[npoints-1].x = mpt.x; points[npoints-1].y = mpt.y; if (ensure_closed) { points[npoints].x = nplp->o.ce.x; points[npoints].y = nplp->o.ce.y; npoints++; } joinsense &= ~joinsense_over; } else join = gs_join_bevel; if (t_den != 0 && ((t_num >= 0 && t_num <= t_den) || (t_num <= 0 && t_num >= t_den))) { double x = xa - xab * t_num / t_den; double y = ya - yab * t_num / t_den; rpoints[nrpoints-1].x = (fixed)x; rpoints[nrpoints-1].y = (fixed)y; joinsense &= ~joinsense_under; } } else { /* Underjoin (in fwd path): * A = plp->o.ce, B = plp->e.co, C = nplp->o.ce, D = nplp->e.co */ double xa = plp->o.ce.x, ya = plp->o.ce.y; double xb = plp->e.co.x, yb = plp->e.co.y; double xc = nplp->o.ce.x, yc = nplp->o.ce.y; double xd = nplp->e.co.x, yd = nplp->e.co.y; double xab = xa-xb, xac = xa-xc, xcd = xc-xd; double yab = ya-yb, yac = ya-yc, ycd = yc-yd; double t_num = xac * ycd - yac * xcd; double t_den = xab * ycd - yab * xcd; code = check_miter(pgs_lp, plp, nplp, pmat, &plp->e.ce, &nplp->o.co, &mpt, false); if (code < 0) return code; if (code == 0) { rpoints[nrpoints-1].x = mpt.x; rpoints[nrpoints-1].y = mpt.y; if (ensure_closed) { rpoints[nrpoints].x = nplp->o.co.x; rpoints[nrpoints].y = nplp->o.co.y; nrpoints++; } joinsense &= ~joinsense_over; } else join = gs_join_bevel; if (t_den != 0 && ((t_num >= 0 && t_num <= t_den) || (t_num <= 0 && t_num >= t_den))) { double x = xa - xab * t_num / t_den; double y = ya - yab * t_num / t_den; points[npoints-1].x = (fixed)x; points[npoints-1].y = (fixed)y; joinsense &= ~joinsense_under; } } } } if ((code = add_points(ppath, points, npoints, moveto_first)) < 0) return code; if ((code = add_points(rpath, rpoints, nrpoints, rmoveto_first)) < 0) return code; npoints = 0; nrpoints = 0; if (nplp == 0) { /* Add a final cap. */ if (end_cap == gs_cap_round) { code = add_pie_cap(ppath, &plp->e); } else { code = cap_points(end_cap, &plp->e, points); npoints = code; } } else if (nplp->thin) { /* no join */ code = cap_points(gs_cap_butt, &plp->e, points); npoints = code; } else if (joinsense == joinsense_cap) { /* Do a cap */ code = add_pie_cap(ppath, &plp->e); if (code >= 0) { /* If the next line is in the opposite direction as the current one * we want to leave the point on the same side as it was * originally. This is required for paths that come to a stop * and then reverse themselves, but may produce more complexity * than we'd really like at the ends of smooth beziers. */ if ((double)(plp->width.x) * nplp->width.x + (double)plp->width.y * nplp->width.y >= 0) code = gx_path_add_line(ppath, plp->e.co.x, plp->e.co.y); } } else if (joinsense & joinsense_ccw) { /* CCW rotation. Join in the forward path. "Underjoin" in the * reverse path. */ if (joinsense & joinsense_over) { /* RJW: Ideally we should include the "|| flags" clause in * the following condition. This forces all joins between * line segments generated from arcs to be round. This would * solve some flatness issues, but makes some pathological * cases incredibly slow. */ if (join == gs_join_round /* || (flags & nf_all_from_arc) */) { code = add_pie_join_fast_ccw(ppath, plp, nplp, reflected); } else { /* non-round join */ code = line_join_points_fast_ccw(pgs_lp, plp, nplp, points, pmat, join); npoints = code; } if (code < 0) return code; } if (joinsense & joinsense_under) { /* The underjoin */ #ifndef SLOWER_BUT_MORE_ACCURATE_STROKING if ((flags & (nf_some_from_arc | nf_prev_some_from_arc)) == 0) { /* RJW: This is an approximation. We ought to draw a line * back to nplp->o.p, and then independently fill any exposed * region under the curve with a round join. Sadly, that's * a) really hard to do, and b) makes certain pathological * filling cases MUCH slower due to the greater number of * "cross-segment" line segments this produces. Instead, * we just skip the line to the middle, and join across the * bottom instead. This is akin to what other graphics libs * do (such as fitz, libart, etc). It's not perfect but in * most cases it's close, and results in faster to fill * paths. */ /* RJW: This goes wrong for some paths, as the 'underjoin' wind * will be the wrong way. See bug 694971 */ code = gx_path_add_line(rpath, nplp->o.p.x, nplp->o.p.y); if (code < 0) return code; } #else if (wide_underjoin(plp, nplp)) { code = gx_path_add_line(rpath, nplp->o.p.x, nplp->o.p.y); if (code < 0) return code; if ((flags & (nf_some_from_arc | nf_prev_some_from_arc)) != 0) { code = gx_path_add_line(rpath, nplp->o.co.x, nplp->o.co.y); if (code < 0) return code; code = gx_path_add_line(rpath, plp->e.ce.x, plp->e.ce.y); if (code < 0) return code; code = gx_path_add_line(rpath, nplp->o.p.x, nplp->o.p.y); if (code < 0) return code; } } #endif code = gx_path_add_line(rpath, nplp->o.co.x, nplp->o.co.y); } } else if (joinsense & joinsense) { /* CW rotation. Join in the reverse path. "Underjoin" in the * forward path. */ if (joinsense & joinsense_over) { /* RJW: Ideally we should include the "|| flags" clause in * the following condition. This forces all joins between * line segments generated from arcs to be round. This would * solve some flatness issues, but makes some pathological * cases incredibly slow. */ if (join == gs_join_round /* || (flags & nf_all_from_arc) */) { code = add_pie_join_fast_cw(rpath, plp, nplp, reflected); } else { /* non-round join */ code = line_join_points_fast_cw(pgs_lp, plp, nplp, rpoints, pmat, join); nrpoints = code; } if (code < 0) return code; } if (joinsense & joinsense_under) { /* The underjoin */ #ifndef SLOWER_BUT_MORE_ACCURATE_STROKING if ((flags & (nf_some_from_arc | nf_prev_some_from_arc)) == 0 && join != gs_join_miter) { /* RJW: This is an approximation. We ought to draw a line * back to nplp->o.p, and then independently fill any exposed * region under the curve with a round join. Sadly, that's * a) really hard to do, and b) makes certain pathological * filling cases MUCH slower due to the greater number of * "cross-segment" line segments this produces. Instead, * we just skip the line to the middle, and join across the * bottom instead. This is akin to what other graphics libs * do (such as fitz, libart, etc). It's not perfect but in * most cases it's close, and results in faster to fill * paths. */ /* RJW: This goes wrong for some paths, as the 'underjoin' wind * will be the wrong way. See bug 694971 */ code = gx_path_add_line(ppath, nplp->o.p.x, nplp->o.p.y); if (code < 0) return code; } #else if (wide_underjoin(plp, nplp)) { code = gx_path_add_line(ppath, nplp->o.p.x, nplp->o.p.y); if (code < 0) return code; if ((flags & (nf_some_from_arc | nf_prev_some_from_arc)) != 0) { code = gx_path_add_line(ppath, nplp->o.ce.x, nplp->o.ce.y); if (code < 0) return code; code = gx_path_add_line(ppath, plp->e.co.x, plp->e.co.y); if (code < 0) return code; code = gx_path_add_line(ppath, nplp->o.p.x, nplp->o.p.y); if (code < 0) return code; } } #endif code = gx_path_add_line(ppath, nplp->o.ce.x, nplp->o.ce.y); } } if (code < 0) return code; if (npoints > 0) { code = add_points(ppath, points, npoints, false); if (code < 0) return code; } if (nrpoints > 0) { code = add_points(rpath, rpoints, nrpoints, false); if (code < 0) return code; } if (ensure_closed) return gx_join_path_and_reverse(ppath, rpath); return 0; } /* Add a CPSI-compatible segment to the path. This handles all the complex * cases. * * This method doesn't support start/end/dash caps, but it's only used from * postscript, so it doesn't need to. */ static int stroke_add_compat(gx_path * ppath, gx_path *rpath, bool ensure_closed, int first, pl_ptr plp, pl_ptr nplp, const gx_device_color * pdevc, gx_device * dev, const gs_gstate * pgs, const gx_stroke_params * params, const gs_fixed_rect * ignore_pbbox, int uniform, gs_line_join join, bool reflected, note_flags flags) { /* Actually it adds 2 contours : one for the segment itself, and another one for line join or for the ending cap. Note CPSI creates negative contours. */ const gx_line_params *pgs_lp = gs_currentlineparams_inline(pgs); gs_fixed_point points[5]; int npoints; bool const moveto_first = true; /* Keeping this code closer to "stroke_add". */ int code; if (plp->thin) { /* We didn't set up the endpoint parameters before, */ /* because the line was thin. Do it now. */ set_thin_widths(plp); adjust_stroke(dev, plp, pgs, true, first == 0 && nplp == 0, flags); compute_caps(plp); } /* The segment itself : */ ASSIGN_POINT(&points[0], plp->o.ce); ASSIGN_POINT(&points[1], plp->e.co); ASSIGN_POINT(&points[2], plp->e.ce); ASSIGN_POINT(&points[3], plp->o.co); code = add_points(ppath, points, 4, moveto_first); if (code < 0) return code; code = gx_path_close_subpath(ppath); if (code < 0) return code; npoints = 0; if (nplp == 0) { /* Add a final cap. */ if (pgs_lp->start_cap == gs_cap_butt) return 0; if (pgs_lp->start_cap == gs_cap_round) { ASSIGN_POINT(&points[npoints], plp->e.co); ++npoints; if ((code = add_points(ppath, points, npoints, moveto_first)) < 0) return code; return add_round_cap(ppath, &plp->e); } ASSIGN_POINT(&points[0], plp->e.ce); ++npoints; ASSIGN_POINT(&points[npoints], plp->e.co); ++npoints; code = cap_points(pgs_lp->start_cap, &plp->e, points + npoints); if (code < 0) return code; npoints += code; } else if (join == gs_join_round) { ASSIGN_POINT(&points[npoints], plp->e.co); ++npoints; if ((code = add_points(ppath, points, npoints, moveto_first)) < 0) return code; return add_round_cap(ppath, &plp->e); } else if (nplp->thin) { /* no join */ npoints = 0; } else { /* non-round join */ bool ccw = (double)(plp->width.x) /* x1 */ * (nplp->width.y) /* y2 */ > (double)(nplp->width.x) /* x2 */ * (plp->width.y) /* y1 */; if (ccw ^ reflected) { ASSIGN_POINT(&points[0], plp->e.co); ++npoints; code = line_join_points(pgs_lp, plp, nplp, points + npoints, (uniform ? (gs_matrix *) 0 : &ctm_only(pgs)), join, reflected); if (code < 0) return code; code--; /* Drop the last point of the non-compatible mode. */ npoints += code; } else { code = line_join_points(pgs_lp, plp, nplp, points, (uniform ? (gs_matrix *) 0 : &ctm_only(pgs)), join, reflected); if (code < 0) return code; ASSIGN_POINT(&points[0], plp->e.ce); /* Replace the starting point of the non-compatible mode. */ npoints = code; } } code = add_points(ppath, points, npoints, moveto_first); if (code < 0) return code; code = gx_path_close_subpath(ppath); return code; } /* Add a CPSI-compatible segment to the path. This handles all the complex * cases. * * This method doesn't support start/end/dash caps, but it's only used from * postscript, so it doesn't need to. */ static int stroke_add_initial_cap_compat(gx_path * ppath, pl_ptr plp, bool adlust_longitude, const gx_device_color * pdevc, gx_device * dev, const gs_gstate * pgs) { const gx_line_params *pgs_lp = gs_currentlineparams_inline(pgs); gs_fixed_point points[5]; int npoints = 0; int code; if (pgs_lp->start_cap == gs_cap_butt) return 0; if (plp->thin) { /* We didn't set up the endpoint parameters before, */ /* because the line was thin. Do it now. */ set_thin_widths(plp); adjust_stroke(dev, plp, pgs, true, adlust_longitude, 0); compute_caps(plp); } /* Create an initial cap if desired. */ if (pgs_lp->start_cap == gs_cap_round) { if ((code = gx_path_add_point(ppath, plp->o.co.x, plp->o.co.y)) < 0 || (code = add_round_cap(ppath, &plp->o)) < 0 ) return code; return 0; } else { ASSIGN_POINT(&points[0], plp->o.co); ++npoints; if ((code = cap_points(pgs_lp->start_cap, &plp->o, points + npoints)) < 0) return npoints; npoints += code; ASSIGN_POINT(&points[npoints], plp->o.ce); ++npoints; code = add_points(ppath, points, npoints, true); if (code < 0) return code; return gx_path_close_subpath(ppath); } } /* Add lines with a possible initial moveto. */ static int add_points(gx_path * ppath, const gs_fixed_point * points, int npoints, bool moveto_first) { int code; if (moveto_first) { code = gx_path_add_point(ppath, points[0].x, points[0].y); if (code < 0) return code; return gx_path_add_lines(ppath, points + 1, npoints - 1); } else { return gx_path_add_lines(ppath, points, npoints); } } /* ---------------- Join computation ---------------- */ /* Compute the points for a bevel, miter, or triangle join. */ /* Treat no join the same as a bevel join. */ /* If pmat != 0, we must inverse-transform the distances for */ /* the miter check. */ static int line_join_points(const gx_line_params * pgs_lp, pl_ptr plp, pl_ptr nplp, gs_fixed_point * join_points, const gs_matrix * pmat, gs_line_join join, bool reflected) { #define jp1 join_points[0] #define np1 join_points[1] #define np2 join_points[2] #define jp2 join_points[3] #define jpx join_points[4] /* * Set np to whichever of nplp->o.co or .ce is outside * the current line. We observe that the point (x2,y2) * is counter-clockwise from (x1,y1), relative to the origin, * iff * (arctan(y2/x2) - arctan(y1/x1)) mod 2*pi < pi, * taking the signs of xi and yi into account to determine * the quadrants of the results. It turns out that * even though arctan is monotonic only in the 4th/1st * quadrants and the 2nd/3rd quadrants, case analysis on * the signs of xi and yi demonstrates that this test * is equivalent to the much less expensive test * x1 * y2 > x2 * y1 * in all cases. * * In the present instance, x1,y1 are plp->width, * x2,y2 are nplp->width, and the origin is * their common point (plp->e.p, nplp->o.p). * ccw will be true iff nplp.o.co (nplp.o.p + width) is * counter-clockwise from plp.e.ce (plp.e.p + width), * in which case we want tan(a-b) rather than tan(b-a). * * We make the test using double arithmetic only because * the !@#&^*% C language doesn't give us access to * the double-width-result multiplication operation * that almost all CPUs provide! */ bool ccw = (double)(plp->width.x) /* x1 */ * (nplp->width.y) /* y2 */ > (double)(nplp->width.x) /* x2 */ * (plp->width.y) /* y1 */; bool ccw0 = ccw; p_ptr outp, np; int code; gs_fixed_point mpt; ccw ^= reflected; /* Initialize for a bevel join. */ ASSIGN_POINT(&jp1, plp->e.co); ASSIGN_POINT(&jp2, plp->e.ce); /* * Because of stroke adjustment, it is possible that * plp->e.p != nplp->o.p. For that reason, we must use * nplp->o.p as np1 or np2. */ if (!ccw) { outp = &jp2; ASSIGN_POINT(&np2, nplp->o.co); ASSIGN_POINT(&np1, nplp->o.p); np = &np2; } else { outp = &jp1; ASSIGN_POINT(&np1, nplp->o.ce); ASSIGN_POINT(&np2, nplp->o.p); np = &np1; } if_debug1('O', "[O]use %s\n", (ccw ? "co (ccw)" : "ce (cw)")); /* Handle triangular joins now. */ if (join == gs_join_triangle) { fixed tpx = outp->x - nplp->o.p.x + np->x; fixed tpy = outp->y - nplp->o.p.y + np->y; ASSIGN_POINT(&jpx, jp2); if (!ccw) { /* Insert tp between np2 and jp2. */ jp2.x = tpx, jp2.y = tpy; } else { /* Insert tp between jp1 and np1. */ ASSIGN_POINT(&jp2, np2); ASSIGN_POINT(&np2, np1); np1.x = tpx, np1.y = tpy; } return 5; } if (join == gs_join_miter && (code = check_miter(pgs_lp, plp, nplp, pmat, outp, np, &mpt, ccw0)) <= 0) { if (code < 0) return code; ASSIGN_POINT(outp, mpt); } return 4; } static int line_join_points_fast_cw(const gx_line_params * pgs_lp, pl_ptr plp, pl_ptr nplp, gs_fixed_point * rjoin_points, const gs_matrix * pmat, gs_line_join join) { /* rjoin_points will be added to a path that is currently at plp->e.ce. */ /* Join will be between plp->e.ce and nplp->o.co */ if (join == gs_join_triangle) { gs_fixed_point tp; tp.x = plp->e.ce.x - nplp->o.p.x + nplp->o.co.x; tp.y = plp->e.ce.y - nplp->o.p.y + nplp->o.co.y; ASSIGN_POINT(&rjoin_points[0], tp); ASSIGN_POINT(&rjoin_points[1], nplp->o.co); return 2; } /* Set up for a Bevel join */ ASSIGN_POINT(&rjoin_points[0], nplp->o.co); return 1; } static int line_join_points_fast_ccw(const gx_line_params * pgs_lp, pl_ptr plp, pl_ptr nplp, gs_fixed_point * join_points, const gs_matrix * pmat, gs_line_join join) { /* join_points will be added to a path that is currently at plp->e.co. */ /* Join will be between plp->e.co and nplp->o.ce */ if (join == gs_join_triangle) { gs_fixed_point tp; tp.x = plp->e.co.x - nplp->o.p.x + nplp->o.ce.x; tp.y = plp->e.co.y - nplp->o.p.y + nplp->o.ce.y; ASSIGN_POINT(&join_points[0], tp); ASSIGN_POINT(&join_points[1], nplp->o.ce); return 2; } /* Set up for a Bevel join */ ASSIGN_POINT(&join_points[0], nplp->o.ce); return 1; } /* ---------------- Cap computations ---------------- */ /* Compute the endpoints of the two caps of a segment. */ /* Only o.p, e.p, width, and cdelta have been set. */ static void compute_caps(pl_ptr plp) { fixed wx2 = plp->width.x; fixed wy2 = plp->width.y; plp->o.co.x = plp->o.p.x + wx2, plp->o.co.y = plp->o.p.y + wy2; plp->o.cdelta.x = -plp->e.cdelta.x, plp->o.cdelta.y = -plp->e.cdelta.y; plp->o.ce.x = plp->o.p.x - wx2, plp->o.ce.y = plp->o.p.y - wy2; plp->e.co.x = plp->e.p.x - wx2, plp->e.co.y = plp->e.p.y - wy2; plp->e.ce.x = plp->e.p.x + wx2, plp->e.ce.y = plp->e.p.y + wy2; #if defined(DEBUG) && !defined(GS_THREADSAFE) if (gs_debug_c('O')) { dlprintf4("[o]Stroke o=(%f,%f) e=(%f,%f)\n", fixed2float(plp->o.p.x), fixed2float(plp->o.p.y), fixed2float(plp->e.p.x), fixed2float(plp->e.p.y)); dlprintf4("\twxy=(%f,%f) lxy=(%f,%f)\n", fixed2float(wx2), fixed2float(wy2), fixed2float(plp->e.cdelta.x), fixed2float(plp->e.cdelta.y)); } #endif } #define px endp->p.x #define py endp->p.y #define xo endp->co.x #define yo endp->co.y #define xe endp->ce.x #define ye endp->ce.y #define cdx endp->cdelta.x #define cdy endp->cdelta.y /* Add a round cap to a path. */ /* Assume the current point is the cap origin (endp->co). */ static int add_round_cap(gx_path * ppath, const_ep_ptr endp) { int code; /* * Per the Red Book, we draw a full circle, even though a semicircle * is sufficient for the join. */ if ((code = gx_path_add_partial_arc(ppath, px + cdx, py + cdy, xo + cdx, yo + cdy, quarter_arc_fraction)) < 0 || (code = gx_path_add_partial_arc(ppath, xe, ye, xe + cdx, ye + cdy, quarter_arc_fraction)) < 0 || (code = gx_path_add_partial_arc(ppath, px - cdx, py - cdy, xe - cdx, ye - cdy, quarter_arc_fraction)) < 0 || (code = gx_path_add_partial_arc(ppath, xo, yo, xo - cdx, yo - cdy, quarter_arc_fraction)) < 0 || /* The final point must be (xe,ye). */ (code = gx_path_add_line(ppath, xe, ye)) < 0 ) return code; return 0; } /* Add a semicircular cap to a path. */ /* Assume the current point is the cap origin (endp->co). */ static int add_pie_cap(gx_path * ppath, const_ep_ptr endp) { int code; if ((code = gx_path_add_partial_arc(ppath, px + cdx, py + cdy, xo + cdx, yo + cdy, quarter_arc_fraction)) < 0 || (code = gx_path_add_partial_arc(ppath, xe, ye, xe + cdx, ye + cdy, quarter_arc_fraction)) < 0 || (code = gx_path_add_line(ppath, xe, ye)) < 0) return code; return 0; } static int do_pie_join(gx_path * ppath, gs_fixed_point *centre, gs_fixed_point *current_orig, gs_fixed_point *current_tangent, gs_fixed_point *final, gs_fixed_point *final_tangent, bool ccw, gs_fixed_point *width) { int code; double rad_squared, dist_squared, F; gs_fixed_point current, tangent, tangmeet; tangent.x = current_tangent->x; tangent.y = current_tangent->y; current.x = current_orig->x; current.y = current_orig->y; /* Is the join more than 90 degrees? */ if ((double)tangent.x * (double)final_tangent->x + (double)tangent.y * (double)final_tangent->y > 0) { /* Yes, so do a quarter turn. */ code = gx_path_add_partial_arc(ppath, centre->x + tangent.x, centre->y + tangent.y, /* Point where tangents meet */ current.x + tangent.x, current.y + tangent.y, quarter_arc_fraction); if (code < 0) return code; current.x = centre->x + tangent.x; current.y = centre->y + tangent.y; if (ccw) { int tmp = tangent.x; tangent.x = -tangent.y; tangent.y = tmp; } else { int tmp = tangent.x; tangent.x = tangent.y; tangent.y = -tmp; } } /* Now we are guaranteed that the remaining arc is 90 degrees or * less. Find where the tangents meet for this final section. */ if (line_intersect(¤t, &tangent, final, final_tangent, &tangmeet) != 0) { return gx_path_add_line(ppath, final->x, final->y); } current.x -= tangmeet.x; current.y -= tangmeet.y; dist_squared = ((double)current.x) * current.x + ((double)current.y) * current.y; rad_squared = ((double)width->x) * width->x + ((double)width->y) * width->y; dist_squared /= rad_squared; F = (4.0/3.0)*(1/(1+sqrt(1+dist_squared))); return gx_path_add_partial_arc(ppath, final->x, final->y, tangmeet.x, tangmeet.y, F); } /* Add a pie shaped join to a path. */ /* Assume the current point is the cap origin (endp->co). */ static int add_pie_join(gx_path * ppath, pl_ptr plp, pl_ptr nplp, bool reflected, bool cap) { int code; gs_fixed_point *current, *final, *tangent, *final_tangent; double l, r; bool ccw; l = (double)(plp->width.x) /* x1 */ * (nplp->width.y) /* y2 */; r = (double)(nplp->width.x) /* x2 */ * (plp->width.y) /* y1 */; if (l == r) { if (cap) return add_pie_cap(ppath, &plp->e); else return gx_path_add_line(ppath, plp->e.ce.x, plp->e.ce.y); } ccw = (l > r); ccw ^= reflected; /* At this point, the current point is plp->e.co */ if (ccw) { current = & plp->e.co; final = &nplp->o.ce; tangent = & plp->e.cdelta; final_tangent = &nplp->o.cdelta; /* Check for no join required */ if (current->x == final->x && current->y == final->y) { return gx_path_add_line(ppath, plp->e.ce.x, plp->e.ce.y); } } else { current = &nplp->o.co; final = & plp->e.ce; tangent = &nplp->o.cdelta; final_tangent = & plp->e.cdelta; code = gx_path_add_line(ppath, plp->e.p.x, plp->e.p.y); if (code < 0) return code; code = gx_path_add_line(ppath, current->x, current->y); if (code < 0) return code; if (current->x == final->x && current->y == final->y) return 0; } if ((code = do_pie_join(ppath, &plp->e.p, current, tangent, final, final_tangent, !reflected, &plp->width)) < 0) return code; if (ccw && ((code = gx_path_add_line(ppath, plp->e.p.x, plp->e.p.y)) < 0 || (code = gx_path_add_line(ppath, plp->e.ce.x, plp->e.ce.y)) < 0)) return code; return 0; } /* Add a pie shaped join to a path. */ static int add_pie_join_fast_cw(gx_path * rpath, pl_ptr plp, pl_ptr nplp, bool reflected) { /* At this point, the current point is plp->e.ce */ if (plp->e.ce.x == nplp->o.co.x && plp->e.ce.y == nplp->o.co.y) return 0; return do_pie_join(rpath, &plp->e.p, &plp->e.ce, &plp->e.cdelta, &nplp->o.co, &nplp->o.cdelta, reflected, &plp->width); } static int add_pie_join_fast_ccw(gx_path * ppath, pl_ptr plp, pl_ptr nplp, bool reflected) { /* At this point, the current point is plp->e.co */ /* Check for no join required */ if (plp->e.co.x == nplp->o.ce.x && plp->e.co.y == nplp->o.ce.y) return 0; return do_pie_join(ppath, &plp->e.p, &plp->e.co, &plp->e.cdelta, &nplp->o.ce, &nplp->o.cdelta, !reflected, &plp->width); } static int join_under_pie(gx_path * ppath, pl_ptr plp, pl_ptr nplp, bool reflected) { int code; gs_fixed_point dirn1, dirn2, tangmeet; double l, r; bool ccw; l = (double)(plp->width.x) /* x1 */ * (nplp->width.y) /* y2 */; r = (double)(nplp->width.x) /* x2 */ * (plp->width.y) /* y1 */; if (l == r) return 0; ccw = (l > r); ccw ^= reflected; if (ccw) { dirn1.x = - plp->width.x; dirn1.y = - plp->width.y; dirn2.x = -nplp->width.x; dirn2.y = -nplp->width.y; if (line_intersect(& plp->o.co, &dirn1, &nplp->e.ce, &dirn2, &tangmeet) != 0) return 0; if ((code = gx_path_close_subpath(ppath)) < 0 || (code = gx_path_add_point(ppath, tangmeet.x, tangmeet.y)) < 0 || (code = gx_path_add_line(ppath,plp->o.co.x,plp->o.co.y)) < 0 || (code = do_pie_join(ppath, &plp->e.p, &plp->o.co, &plp->o.cdelta, &nplp->e.ce, &nplp->e.cdelta, !reflected, &plp->width))) return code; } else { if (line_intersect(& plp->o.ce, & plp->width, &nplp->e.co, &nplp->width, &tangmeet) != 0) return 0; if ((code = gx_path_close_subpath(ppath)) < 0 || (code = gx_path_add_point(ppath, tangmeet.x, tangmeet.y)) < 0 || (code = gx_path_add_line(ppath,nplp->e.co.x,nplp->e.co.y)) < 0 || (code = do_pie_join(ppath, &plp->e.p,&nplp->e.co,&nplp->e.cdelta, &plp->o.ce, &plp->o.cdelta, !reflected, &plp->width))) return code; } return 0; } /* Compute the points for a non-round cap. */ /* Return the number of points. */ static int cap_points(gs_line_cap type, const_ep_ptr endp, gs_fixed_point *pts /*[3]*/) { #define PUT_POINT(i, px, py)\ pts[i].x = (px), pts[i].y = (py) switch (type) { case gs_cap_butt: PUT_POINT(0, xo, yo); PUT_POINT(1, xe, ye); return 2; case gs_cap_square: PUT_POINT(0, xo + cdx, yo + cdy); PUT_POINT(1, xe + cdx, ye + cdy); return 2; case gs_cap_triangle: /* (not supported by PostScript) */ PUT_POINT(0, xo, yo); PUT_POINT(1, px + cdx, py + cdy); PUT_POINT(2, xe, ye); return 3; default: /* can't happen */ return_error(gs_error_unregistered); } #undef PUT_POINT }